MDIO Decode
The Media Data Input/Output (MDIO) decoder provides a fast and easy way to understand and correlate MDIO bus traffic to the management of PHYs or physical layer devices in media access controllers (MACs).

10-Gigabit Ethernet Decode
The 10-Gigabit Ethernet decode option for Teledyne LeCroy oscilloscopes provides link layer decode information annotated on the 10-Gigabit physical layer waveform. This provides the ability to view protocol traffic on the oscilloscope. It also aids in debugging problems that are not solely analog or digital in nature - issues not evident with a Protocol Analyzer

14GBIT-80B-SYMBOL-TD
Rapidly pinpoint and debug problems with NRZ, 8b/10b and 64b/66b signals using the high-speed serial trigger and decode options. Hardware trigger products with maximum bitrates of 6.5 and 14.1 Gbps are available for WaveMaster 8 Zi-A, LabMaster 9 Zi-A and LabMaster 10 Zi series oscilloscopes, and include 8b/10b and 64b/66b decoders.

CAN FDbus TD
The CAN FD Trigger Decode (TD) solution provides high performance triggers and transparent color-coded decode overlays, protocol tables, and search capabilities for both CAN and CAN FD.

CAN FDbus TDME
The CAN FD Trigger, Decode, Measure/Graph and Eye Diagram (TDME) solution provides high performance triggers and transparent color-coded decode overlays, protocol tables, and search capabilities, Measure/Graph (M) capability with automated measurement and graphing tools, and Eye Diagram (E) capability for physical layer signal assessment and debug for both CAN and CAN FD. Symbolic DBC files may be used to set up the trigger, display symbolic decodes, and select parameters for serial digital data extraction to an analog value.

CAN FDbus TDME Symbolic
The CAN FD Trigger, Decode, Measure/Graph and Eye Diagram solution with Symbolic support (TDME Symbolic) provides high performance triggers and transparent color-coded decode overlays, protocol tables, and search capabilities, Measure/Graph (M) capability with automated measurement and graphing tools, and Eye Diagram (E) capability for physical layer signal assessment and debug for both CAN and CAN FD. Symbolic DBC files may be used to set up the trigger, display symbolic decodes, and select parameters for serial digital data extraction to an analog value.

CANbus TDME Symbolic
The CAN Trigger, Decode, Measure/Graph and Eye Diagram solution with Symbolic CAN support (TDME Symbolic) provides high performance triggers, transparent color-coded decode overlays, protocol tables, and search capabilities, Measure/Graph (M) capability with automated measurement and graphing tools, and Eye Diagram (E) capability for physical layer signal assessment and debug. Symbolic DBC files may be used to set up the trigger, display symbolic decodes, and select parameters for serial digital data extraction to an analog value

D-PHYbus D - Decode option
The MIPI D-PHY decode is the ideal tool for powerful system level protocol debug as well as problem solving for signal quality issues. The D-PHY decode solution adds a unique set of tools to your oscilloscope, simplifying how you design and debug MIPI D-PHY, CSI-2 and DSI signals.

D-PHYbus DP - Decode and Physical layer test option
The MIPI M-PHY and D-PHY Decode and Physical Layer Test is the ideal tool for powerful system level protocol debug as well as problem solving for signal quality issues. The D-PHY decode solution adds a unique set of tools to your oscilloscope, simplifying how you design and debug MIPI D-PHY, CSI-2 and DSI signals.

DigRF 3G bus
The DigRF 3G decode is the ideal tool for powerful system level protocol debug as well as problem solving for signal quality issues. The DigRF 3G decode adds a unique set of tools to your oscilloscope, simplifying how you design and debug MIPI digital RF systems.

DigRF v4 bus
The DigRF 3G and v4 decode are the ideal tools for powerful system level protocol debug as well as problem solving for signal quality issues. The DigRF decodes add a unique set of tools to your oscilloscope, simplifying how you design and debug MIPI digital RF systems.

Embedded System Bundle TD
The Embedded Bundle Trigger and Decode (TD) contains the capabilities included in the I2Cbus, SPIbus, and UART-RS232bus TD products. For more information on this product, please see the product pages for I2Cbus TD, SPIbus TD, and UART-RS232bus TD.

Embedded System Bundle TDME
The Embedded Bundle Trigger, Decode, Measure/Graph and Eye Diagram(TDME) contains the capabilities included in the I2Cbus, SPIbus, and UART-RS232bus TDME products. For more information on this product, please see the product pages for I2Cbus TDME, SPIbus TDME, and UART-RS232bus TDME.

M-PHYbus D - Decode option
The MIPI M-PHY and D-PHY Decode and Physical Layer Test is the ideal tool for powerful system level protocol debug as well as problem solving for signal quality issues. The D-PHY decode solution adds a unique set of tools to your oscilloscope, simplifying how you design and debug MIPI D-PHY, CSI-2 and DSI signals.

M-PHYbus DP - Decode and Physical layer test option
The MIPI M-PHY and D-PHY Decode and Physical Layer Test is the ideal tool for powerful system level protocol debug as well as problem solving for signal quality issues. The D-PHY decode solution adds a unique set of tools to your oscilloscope, simplifying how you design and debug MIPI D-PHY, CSI-2 and DSI signals.

Manchester Decode
Manchester coding is a line code in which the encoding of each data bit has at least one transition and 1s and 0s have equal bit width and therefore has no DC component. Manchester signals are self-clocking, which means that a clock signal can be recovered from the encoded data. Manchester Configurable protocol decoder enables grouping bits using various combinations of bit rate, polarity, idle condition, time out and more to decipherable messages. It allows decode of various protocols developed using Manchester encoding scheme.

NRZbus D
NRZ (non-return-to-zero) line code is a binary code in which 1s are represented by one significant condition (usually a positive voltage) and 0s are represented by some other significant condition (usually a negative voltage), with no other neutral or rest condition. NRZ Configurable protocol decoder enables grouping bits using various combinations of bit rate, polarity, idle condition, time out and more to decipherable messages. It allows decode of various protocols developed using NRZ encoding scheme.

SAS bus D
The SASbus D decode annotation option is available for most Teledyne LeCroy oscilloscopes. It permits link and data layer decoding of 1.5, 3, 6, or 12 Gb/s SAS physical layer signals. Decode information is annotated on the physical layer waveform. Various sections of the protocol are color-coded to make it easy to understand the protocol traffic.

SENTbus D
High-resolution SENT sensor and ECU message frames are intuitively decoded on the waveform, provided in an interactive table, and payload content search tools make debugging fast and effective.

SpaceWirebus D
The SpaceWire decode adds a unique set of tools to your Teledyne LeCroy oscilloscope that simplifies the design, debug, and maintenance of SpaceWire systems. The high speed SpaceWire data stream is annotated directly on the physical layer waveforms. Various sections of the protocol are color-coded to make it easy to understand the protocol traffic. The decoder provides an interactive table, search, and zoom to make debugging fast and effective.

SPMI Decode
The MIPI System Power Management Interface (SPMI) decoder provides a fast and easy way to understand and correlate SPMI bus traffic to DC power rails and power management IC (PMIC) operations in mobile, handheld, and battery-powered embedded systems.

UNIPRObus D
The MIPI UniPro Protocol Decoder analyzes acquired M-PHY analog waveforms and provides insight into multiple levels of UniPro protocol information. Data and Control frames are presented in an intuitive table format, where selecting a frame expands its content to a color-coded symbolic level, simultaneously creating a zoom. Decode annotation information is displayed on the physical layer waveform for a quick reference.

USB 3.0 bus
The USB 3.0 decode option for Teledyne LeCroy oscilloscopes provides link layer decode information annotated on the USB 3.0 physical layer waveform. This provides the ability to view protocol traffic on the oscilloscope and verify that the link is alive and transmitting properly. It also aids in debugging problems that are not solely analog or digital in nature, such as interoperability issues, uncertain error causes, and physical layer issues not evident with a Protocol Analyzer.

USB2-HSICbus D
The comprehensive and intuitive deocde and easy to navigate table display enable a powerful toolset to quickly debug a USB 2.0 HSIC powered system. Combine it with ProtoSync to get a full view of all the USB 2.0 layers.

The trigger permits a conditional (<. <=, =, >, >=, <>, inside a range, outside a range) setup for the DATA condition. This is especially useful in situations where abnormal events should be monitored, such as when a CAN node broadcasts a low or high engine RPM or coolant pressure.

Flexible Error Frame Triggering ("T")

Select to trigger on any combination of Checksum, Header Parity, or Sync Byte error frame types. Additional, Checksum Error allows further definition for Frame ID, LIN Version, and Number of Data Bytes.

Trigger Flexibly Across Data Bytes("T")

Many vehicle bus software architectures are very message dense, and data for a single message is spread across multiple data bytes. Our LIN trigger and measurement toolsets permit isolation of specific bit-level data patterns in one or more data bytes, e.g., data location in bits 18-26 in data bytes 2 and 3. This provides significant advantages in isolating the exact information or behavior you need.

Intuitive, Color-coded Decode Overlays ("D")

A transparent overlay with color-coding for specific portions of each protocol and the entire message frame makes it easy to understand your serial data information. Unlike other solutions, with protocol decode information away from the signal, our solution correlates the waveform and the protocol decode directly on the display. As the acquisition length is expanded or shortened, the decode overlay will adjust to show you just the right amount of information.

Interactive Table Summarizes Results ("D")

Turn the oscilloscope into a protocol analyzer with a tabular display of decoded information. Customize the table to show only the data of interest and touch a message in the table to automatically zoom to it and display it on the screen. Export the table for offline analysis. Up to four different decoded signals of any type may be simultaneously displayed in the table.

Measure/Graph Tools for Validation Efficiency ("M")

Quickly validate cause and effect with automated timing measurements to or from an analog signal or another serial message. Make multiple measurements in a single long acquisition to quickly acquire statistics during corner-case testing. Serial (digital) data can be extracted to an analog value and graphed to monitor system performance over time, as if it was probed directly. Complete validation faster and gain better insight.

Eye Diagrams ("E")

Rapidly display an eye diagram of your packetized low-speed serial data signal without additional setup time. Use eye parameters to quantify system performance and apply a standard or custom mask to identify anomalies. Mask failures can be indicated and can force the scope into Stop mode.